h a l f b a k e r yactual product may differ from illustration
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pre-control control
Extend plane Pinochio nose cone, AI adjusts the shape, Wings, control surfaces use the flow. | |
This is a control surface out in front of the plane, that the plane drafts and utilizes the designed flow.
The nose cone is constructed so as to be able to telescope a few metres in front of the plane. The cone's shape is dynamic due to micro hydraulics and control electronics plumbed centrally from
the plane.
This chameleon of shape takes the initial airflow and minutely changes it for the advantage of plane. This morphing will help with weather conditions, turning and cross winds by deflecting initial air flows and ironing out turbulence to a linear flow . Think flat water behind a ship.
Of course, designing the shape needed, for any set of conditions, is mathematically intensive, especially for a dynamic surface and will have be designed using AI learning algorithms.
Now McPlaney Plane Face, has a nose. Possible? or am I lying air flow at speed.
[link]
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//Think flat water behind a ship.// |
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I'm thinking that. By that analogy, what this idea proposes is a
second plane in front of the first plane, to do the hard work of
smoothing the air flow to the benefit of the first plane. However,
the first plane has to carry the second plane, and must enable it
to do its work while holding it out at arm's length into the
turbulent air - a posture which, to me, suggests mechanical
disadvantage. |
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Maybe what you need is a separate, sacrificial aircraft with
really poor fuel efficiency, so that the following aircraft can claim
superior efficiency and performance. |
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Scale is a factor here, the first plane is some magnitude smaller. Complex waves//flows spread out from the initial point. And in a 175 billion machine learning parameter economy Droopy dynamics can be a bit more, well dynamic. |
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//Maybe what you need is a separate, sacrificial aircraft// whose efficiency could also be improved by giving it a third smaller aeroplane in front of it &ce. |
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And to the sides. The Recursive V formation is the operating flight procedure. |
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Take a look at The Concorde. |
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[-] Bad Science. Adds drag for no benefit. |
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// inlet cones, droop nose, retractable canards... // |
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Inlet cones are there to modify airflow velocity into the engine - a necessary part of supersonic flight. |
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Droop noses are to give improved visibility when landing a delta-wing airframe demanding a high angle of attack. |
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Canards are active control surfaces, again often used with delta planforms. |
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Any dynamically variable system is going to add mass, complexity, and more possible points of failure - thus should be avoided if at all possible. |
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It's a lie we say, you take that back RIGHT NOW ... Fake News ! Fake News ! |
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Evolutionary algorithms can find solutions that shock even the design programmers.So, in this environment of computationally looking under every rock, even strange, against the grain, ideas can have solutions. |
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Good ones? time will tell. |
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